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Brachial plexus neuroma at the truncated extremity|Cryoablation |55|Male
Brachial plexus neuroma at the truncated extremity|Cryoablation |55|Male
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Imaging Cryoablation | Ablations: Cryo, Microwave, & RFA
Imaging Cryoablation | Ablations: Cryo, Microwave, & RFA
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IR in Egypt and Ethiopia | AVIR International-IR Sessions at SIR2019 MiddleEast & Africa Focus
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Cryoablation Advantages and Disadvantages | Ablations: Cryo, Microwave, & RFA
Cryoablation Advantages and Disadvantages | Ablations: Cryo, Microwave, & RFA
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Microwave Ablation - What it is and how it works | Ablations: Cryo, Microwave, & RFA
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Cone Beam CT | Interventional Oncology
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Indirect Angiography | Interventional Oncology
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Case 1 - Non-healing heel wound, Rutherford Cat. 5, previous stroke | Recanalization, Atherectomy | Complex Above Knee Cases with Re-entry Devices and Techniques
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Case 11: Bleeding Tracheostomy Site | Emoblization: Bleeding and Trauma
Case 11: Bleeding Tracheostomy Site | Emoblization: Bleeding and Trauma
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The Procedure - Creating a Deep Fistula | Pecutaneous Creation of Hemodialysis Fistulas
The Procedure - Creating a Deep Fistula | Pecutaneous Creation of Hemodialysis Fistulas
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Case 10: Peritoneal Hematoma | Emoblization: Bleeding and Trauma
Case 10: Peritoneal Hematoma | Emoblization: Bleeding and Trauma
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Treatment Options- TransCarotid Artery Revascularization- TCAR | Carotid Interventions: CAE, CAS, & TCAR
Treatment Options- TransCarotid Artery Revascularization- TCAR | Carotid Interventions: CAE, CAS, & TCAR
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Cryoablation - What it is and how it works | Ablations: Cryo, Microwave, & RFA
Cryoablation - What it is and how it works | Ablations: Cryo, Microwave, & RFA
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Muscoskeletal Ablation | Interventional Oncology
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Geniculate Artery Embolization (Knee) A US Clinical Study | Geniculate Artery Embolization for Arthritic Pain Why How & Results
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Duplex Ultrasound | Determining the Endpoints of CLI Interventions
Duplex Ultrasound | Determining the Endpoints of CLI Interventions
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RFA Advantages and Disadvantages | Ablations: Cryo, Microwave, & RFA
RFA Advantages and Disadvantages | Ablations: Cryo, Microwave, & RFA
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Renal Ablation | Interventional Oncology
Renal Ablation | Interventional Oncology
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Pulmonary Ablation | Interventional Oncology
Pulmonary Ablation | Interventional Oncology
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Radiology in Algeria | IR In Algeria, UAE - PAIRS Meeting
Radiology in Algeria | IR In Algeria, UAE - PAIRS Meeting
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Why is Staging Important | Interventional Oncology
Why is Staging Important | Interventional Oncology
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Why Do We Need Different Directions For Occlusions? | AVIR CLI Panel
Why Do We Need Different Directions For Occlusions? | AVIR CLI Panel
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TEVAR Case | TEVAR w/ Laser Fenestration of Intimal Dissection Flap
TEVAR Case | TEVAR w/ Laser Fenestration of Intimal Dissection Flap
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Introduction- Nursing Management in Prostate Artery Embolization | Nursing Management in Prostate Artery Embolization
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Microwave Ablation Advantages and Disadvantages | Ablations: Cryo, Microwave, & RFA
Microwave Ablation Advantages and Disadvantages | Ablations: Cryo, Microwave, & RFA
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RFA Probe types | Ablations: Cryo, Microwave, & RFA
RFA Probe types | Ablations: Cryo, Microwave, & RFA
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Massive PE | Pulmonary Emoblism Interactive Lecture
Massive PE | Pulmonary Emoblism Interactive Lecture
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Adrenal gland mass next to aorta | Heat sink / Cold sink | Cryoablation Case | Ablations: Cryo, Microwave, & RFA
Adrenal gland mass next to aorta | Heat sink / Cold sink | Cryoablation Case | Ablations: Cryo, Microwave, & RFA
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Balloon Pulmonary Angioplasty | Management of Patients with Acute & Chronic PE
Balloon Pulmonary Angioplasty | Management of Patients with Acute & Chronic PE
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The Ways to Recanalize the Below the Knee Vessels | AVIR CLI Panel
The Ways to Recanalize the Below the Knee Vessels | AVIR CLI Panel
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Cryoablation probes and ice ball shapes | Ablations: Cryo, Microwave, & RFA
Cryoablation probes and ice ball shapes | Ablations: Cryo, Microwave, & RFA
ablateablationantennaaortachaptercryoablationfreezeneedleproberounded
Transcript

And this is a 55-year-old fire fighter, who ended up with

up with a right upper extremity amputation, synovial sarcoma. And so, in ultra sound basically shows this brachial plexus neuroma, right here. This is an image showing the probe line longitudinally through the

brachial plexus neuroma. The black arrows down here show the brachial plexus with this big neuroma on top of it and that's the ablation probe through it. A kind of surgical oblique image basically showing the two probes do it. Here's that T2 image with fast sat showing that neuroma right here

in surgical plane. So again from a more traditional axio imaging approach, the scalene muscles are outlined in green here with the neuroma in red. And bone window showing the probe right into the neuroma splitting the scalene musculature and here's a soft tissue when the're showing

the same thing. So, this is kinda of borrowing a lot of things that actually Dr.Prologo who'll talk about in a second has turned is really kind of a pioneer in this space for it. This is literature from dorsal penile nerve ablation which is a technique

he developed for premature ejaculation. And similarly pudental neuralgia in 2013 and other people that he put together. And so I'm kind of piggy banking on top of him. He's kind of the captain of this ship but he's definitely made me a believer. I tell people he's taken me to the cyroablation for nerve pain church

and I'm definitely singing his praises at this point.

terms of imaging my favorite aspect of cryoablation is the fact that you can see the ice ball very well on CT and most procedures are done with CT guidance right so as you can see this is

a renal ablation the probe has been placed you can see the ice bowl forming around the probe right so that's very predictable you can see exactly where it is the only problem with cryoablation is that that ice bowl is not

necessarily the lethal ice ball right so that maximal ice ball is really your zero Degree and in actual fact the lethal zone is about five millimeters in from that so anytime you do a cryoablation you want to weigh over

freeze essentially to get those margins that you want so that's one important thing to remember the ice ball is not the lethal it's really five millimeters short of that okay so a little more information by cryoablation you don't

have to spend too much time on this but the idea is that the more energy you put in the larger ice ball you can get and so essentially more probes you place can just supplement that energy to increase the size of the ice ball so advantages

next is me talking about Egypt and Ethiopia and how I are how IRS practice in Egypt and Ethiopia and I think feather and Musti is gonna talk a little bit about Ethiopia as well he's got a

lot of experience about in about Ethiopia I chose these two countries to show you the kind of the the the the difference between different countries with within Africa Egypt is the 20th economy worldwide by GDP third largest

economy in Africa by some estimates the largest economy in Africa it's about a hundred million people about a little-little and about thirty percent of the population in the u.s. 15 florist's population worldwide and has

about a little over a hundred ir's right now 15 years ago they had less than ten IRS and fifteen years ago they had maybe two to three IRS at a hundred percent nowadays they're exceeding a hundred IRS so tremendous gross in the last 15 years

in the other hand Ethiopia is a very similar sized country but they only have three to five IRS that are not a hundred percent IRS and are still many of them are under training so there are major differences between countries within

within Africa countries that still need a lot of help and a lot of growth and countries that are like ten fifteen years ahead as far as as far as intervention ready intervention radiology

most of the practice in Ethiopia are basic biopsies drainages and vascular access but there is new workshops with with embolization as well as well as well as vascular access in Egypt the the ir practice is heavily into

interventional oncology and cancer that's the bulk that's the bulk of their of their practices you also get very strong neuro intervention radiology and that's mostly most of these are French trained and not

American trains so they're the neuro IRS in Egypt or heavily French and Belgian trains with with french-speaking influence but the bulk of the body iron that's not neuro is mostly cancer and it involves y9e tastes ablations high-end

ablations there's no cryoablation in Egypt there is high-end like like a nano knife reverse electric race electroporation in Egypt as well but there is no cryo you also get a specialty embolization such as fibroids

prostate and embroiders are big in Egypt they're growing very very rapidly especially prostates hemorrhoids and fibroids is an older one but it's still there's still a lot of growth for fibroid embolization zyou FES in Egypt

there's some portal portal intervention there's a lot of need for that but not a lot of IRS are actually doing portal intervention and then there's nonvascular such as billary gu there's also vascular access a lot of

the vascular access is actually done by nephrology and is not done by not not done by r is done by some high RS varicose veins done by vascular surgery and done by IRS as an outpatient there's a lot of visceral angiography as well

renal and transplants stuff so it's pretty high ends they do not do P ad very few IR s and maybe probably two IR s in the country that actually do P ad the the rest of the P ad is actually endovascular PA DS done by vascular

surgery a Horta is done all by vascular surgery and cardiothoracic surgery it's not done it's not done by IR IR s are asked just to help with embolization sometimes help with trying to get a catheter in a certain area but it's

really run by by vascular surgeons but but most more or less it's it's the whole gamut and I'm going to give you a little example of how things are different that when it comes to a Kannamma 'kz there's no dialysis work

they don't do Pfister grams they don't do D clots the reason for that is the vascular surgeons are actually very good at establishing fishless and they usually don't have a

lot of problems with it sometimes if the fistula is from Beau's door narrowed it's surgically revised they do a surgical thrombectomy because it's a lot cheaper it's a lot cheaper than balloons sheaths and and trying to and try a TPA

is very expensive it's a lot cheaper for a surgeon to just clean it out surgically and resuture it there's no there's no inventory there are no expensive consumables so we don't see dialysis as far as fistula or dialysis

conduits at all in Egypt and that's usually a trend in developed in developed countries next we'll talk

of cryoablation it's gentler than both microwave and RF a you can use it in a lot of locations because of that you can visualize the ice ball with CT multiple probes means potentially huge ablation zones and I'll show you an example of

that it's not painful and for me I know that I don't know about everyone else in the room but our anesthesia assistance is is very spotty or sporadic so it's nice to do stuff with conscious sedation in which case cryoablation you can

absolutely do most places with conscious sedation it's not painful at all whereas if you've done microwave you know the moment you turn the probe on the patient wants to punch you so so it's not particularly painful you can do it with

sedation and it has this immuno genic response that we're starting to learn more about right so when you cook tissue your since you just cha reverie and you just cook all the proteins and all the membrane of the cell with cryoablation

you actually keep some of the proteins in tact so what happens is as the cell dies your immune response comes in and it recognizes those tumor antigens right those tumor proteins and there's been lots of reports of where you oblate for

instance a renal mass and the patient's lung nodules will regress because of that so that's a very nice feature of it is that's got this immuno genic response and I'll use that often times if I'm doing a lung ablation for instance and

there's other nodules you can see a regression of those nodules the disadvantage as well you need you know there's these repeated freezes right so you do these freeze thaw cycles you go ten fighting you know ten freeze five

for ten freeze five for that ends up being a pretty long freeze time right and even if you do the triple freeze protocol which I can talk a little bit in a bit here you can see it ends up adding up a lot of time so the time you

save on not putting the patient to sleep and getting general anesthesia actually lose on the backend when you're standing and staring at the probes freezing whereas my crew of ablation as me as you know 10 minutes and you're

done there is this idea of a cold sink so like RFA if you put the probe right up against the blood vessel it's unlikely that that ice bowl is going to propagate into that blood vessel and you can use

that to your advantage once again I'll show you an example of that but cold sink is technically also a disadvantage and one of the main things people worry about with cryoablation is the bleeding aspect right so unlike our fa or

microwave you're essentially cooking the tissue it's a Bovie right you're very unlikely to have bleeding whereas cryo you freeze the tissue and when you thought all those blood vessels are now very porous and they can bleed and so

one of the concerns with cryo is that you have bleeding and you you'll often see this especially in renal and long and then do some early studies where where physicians were doing large liver oblations and they were getting into

something called cryo shock which we'll talk about in a little bit that's probably overhyped from the earlier studies but for that reason many people do not use cryoablation in the liver they would prefer to use microwave

so that was cryoablation and then the final modality to talk about is

microwave ablation this one should be relatively quick because the idea is pretty simple right this probe is got this electromagnetic energy it's in between the 924 50 megahertz range and basically like RF it causes the water

molecules adjacent to oscillate right so excuse me as you can see it creates this zone or these this this area of electromagnetic activity and all of the water molecules in that area will be activated at once

unlike RF a right so when it's right next to the probe the water molecules oscillate and then the temperature propagates by and by conduction this will essentially create this zone and that

immediately we'll we'll activate those tissues so if you've done microwave ablation you know if you do an ablation of a hundred watts for two minutes you'll get a three centimeter burn it's literally instantaneous as you turn it

on you get this huge burn and then after that anywhere between two minutes and ten minutes you're really only getting about another centimeter of burn and the reason you're doing that is because that's the the passive conduction so it

is very rapid it doesn't have the heat sink issues that RFA does as I mentioned there's this radius of molecules that are activated around the probe the size that radius depends on the wave link and the probe properties there are no

impedance issues so unlike RF a where you want to heat slowly microwave is instantaneous and it just cooks the tissue around the the probe many of the antennas have internal saline perfusion and that's just really to generate

uniform heating and prevent the heat from propagating along the shaft because you obviously don't want it to propagate back towards the skin same ideas are FA right so you want to increase the temperature to greater than 50 degrees

Celsius for about four to six minutes you get coagulation necrosis and you need about a point five a five millimeter margin on that advantages a

know we're running a bit short on time so I want to briefly just touch about

some techniques with comb beam CT which are very helpful to us there are a lot of reasons why you should use comb beam CT it gives us the the most extensive anatomic understanding of vascular territories and the implications for

that with oncology are extremely valuable because of things like margin like we discussed here's an example of a patient who had a high AF P and their bloodstream which tells us that they have a cancer in her liver we can't see

it on the CT there but if you do a cone beam CT it stands up quite nicely why because you're giving levels of contrast that if you were to give them through a peripheral IV it would be toxic to the patient but when you're infusing into a

segment the body tolerates at the problem so patient preparation anxa lysis is key you have them exhale above three seconds prior to that there's a lot of change to how we're doing this people who are introducing radial access

power injection anywhere from about 50 to even sometimes thirty to a hundred percent contrast depends on what phase you're imaging we have a Animoto power injector that allows us to slide what contrast concentration we like a lot of

times people just rely on 30% and do their whole the case with that some people do a hundred percent image quality this is what it looks like when someone's breathing this is very difficult to tell if there's complete

lesion enhancement so if you do your comb beam CT know it looks like this this is trying to coach the patient and try to get them to hold still and then this is the patient after coaching which looks like this so you can tell that you

have a missing portion of the lesion and you have to treat into another segment what about when you're doing an angio and you do a cone beam CT NIT looks like this this is what insufficient counts looks like on comb beam so when you see

these sort of Shell station lines that are going all over the screen you have to raise dose usually in larger patients but this is you know you either slow down the acquisition speed of your comb beam or

you raise dose this is what it looks like after we gave it a higher dose protocol it really changes everything those lines are still there but they're much smaller how do you know if you have enhancement or a narrow artifact you can

repeat with non-contrast CT and give the patient glucagon and you can find the small very these small arteries that pick off the left that commonly profuse the stomach the right gastric artery you can use your comb beam CT to find

non-target evaluation even when your angio doesn't suggest it so this is a patient they have recurrent HCC we didn't angio from here those arteries down there where those coils were looked funny even though the patient was

quote-unquote coiled off we did a comb beam CT and that little squiggly C shape structures that duodenum that's contrast going in it this would be probably a lethal event for the patient or certainly would require surgery if you

treated that much with y9t reposition the catheter deeper towards the lesion and you can repeat your comb beam CT and see that you don't have an hands minh sometimes you have these little accessory left gastric artery this is

where we really need your help you know a lot of times everyone's focused and I think the more eyes the better for these kind of things but we're looking for these little tiny vessels that sometimes hop out of the liver and back into the

stomach or up into the esophagus there's a very very small right gastric artery in this picture here this patient post hepatectomy that rides along the inferior surface of the liver it's a little curly cube so and this is a small

esophageal branch so when you do comb beam TT this is what the stomach looks like when it enhances and this is what the esophagus looks like when it enhances you can do non contrast comb beam CTS to confirm ablation so you have

a lesion this is the comb beam CT for enhancement you treat with your embolic and this is a post to determine that you've had completely shin coverage and you can see how that correlates a response so the last thing we're going

to talk about is indirect angiography this is kind of a neat trick to suggest to your intervention list as a problem solver we were asked to ablate this lesion and it looked kind of funny this patient had a resection for HCC they

thought this was a recurrence so we bring the comb beam CT and we do an angio and it doesn't enhance so this is an image here of indirect port ography so what you can do is an SMA run and see at which point along the

run do you pacify the portal vein and you just set up your cone beam CT for that time so you just repeat your injection and now your pacifying the entire portal vein even though you haven't selected it and what to show

well this was a portal aneurysm after resection with a little bit of clot in it the patient went on some aspirin and it resolved in three months so back to our first patient what do you do for someone who has HCC that's invading the

heart this patient underwent 2y 90s bland embolization microwave ablation chemotherapy and SBRT and he's an eight-year survivor so it's one of those things where certainly with the correct patient selection you can find the right

things to do for someone I think that usually our best results come from our interdisciplinary consensus in terms of trying to use the unique advantages that individual therapies have and IO is just one of those but this is an important

lesson to our whole group that you know a lot of times you get your best results when you use things like a team approach so in summary there are applications to IO prior to surgery to make people surgical candidates there are definitive

treatments ie your cancer will be treated definitively with curative intent a lot of times we can save when people have tried cure intent and weren't able to and obviously to palliate folks to try to buy them time

and quality of life thermal ablation is safe and effective for small lesions but it's limited by the adjacent anatomy y9t is not an ischemic therapy it's an ablative therapy you're putting small ablative radioactive particles within

the lesion and just using the blood supply as a conduit for your brachytherapy and you can use this as a new admin application to make people safer surgical candidates when you apply to the entire ride a panic globe

thanks everyone appreciate it [Applause] [Music]

so just a compliment what we everybody's talked about I think a great introduction for diagnosing PID the imaging techniques to evaluate it some of the Loney I want to talk about some of the above knee interventions no disclosures when it sort of jumped into

a little bit there's a 58 year old male who has a focal non-healing where the right heel now interestingly we when he was referred to me he was referred to for me for a woman that they kept emphasizing at the anterior end going

down the medial aspect of the heel so when I literally looked at that that was really a venous stasis wound so he has a mixed wound and everybody was jumping on that wound but his hour till wound was this this right heel rudra category-five

his risk factors again we talked about diabetes being a large one that in tandem with smoking I think are the biggest risk factors that I see most patient patients with wounds having just as we talked about earlier we I started

with a non-invasive you can see on the left side this is the abnormal side the I'm sorry the right leg is the abnormal the left leg is the normal side so you can see the triphasic waveforms the multiphasic waveforms on the left the

monophasic waveforms immediately at the right I don't typically do a lot of cross-sectional imaging I think a lot of information can be obtained just from the non-invasive just from this the first thing going through my head is he

has some sort of inflow disease with it that's iliac or common I'll typically follow within our child duplex to really localize the disease and carry out my treatment I think a quick comment on a little bit of clinicals so these

waveforms will correlate with your your Honourable pencil Doppler so one thing I always emphasize with our staff is when they do do those audible physical exams don't tell me whether there's simply a Doppler waveform or a Doppler pulse I

don't really care if there's not that means their leg would fall off what I care about is if monophasic was at least multiphasic that actually tells me a lot it tells me a lot afterwards if we gain back that multiphase the city but again

looking at this a couple of things I can tell he has disease high on the right says points we can either go PITA we can go antegrade with no contralateral in this case I'll be since he has hide he's used to the right go contralateral to

the left comment come on over so here's the angio I know NGOs are difficult Aaron when there's no background so just for reference I provided some of the anatomy so this is the right you know groin area

right femur so the right common from artery and SFA you have a downward down to the knee so here's the pop so if we look at this he has Multi multi multiple areas of disease I would say that patients that have above knee disease

that have wounds either have to level disease meaning you have iliac and fem-pop or they at least have to have to heal disease typically one level disease will really be clot against again another emphasis a lot of these patients

since they're not very mobile they're not very ambulatory this these patients often come with first a wound or rest pain so is this is a patient was that example anyway so what we see again is the multifocal occlusions asta knows

he's common femoral origin a common femoral artery sfa origin proximal segment we have a occlusion at the distal sfa so about right here past the air-duct iratus plus another occlusion at the mid pop to talk about just again

the tandem disease baloney he also has a posterior tibial occlusion we talked about the fact that angio some concept so even if I treat all of this above I have to go after that posterior tibial to get to that heel wound and complement

the perineal so ways to reach analyze you know the the biggest obstacle here is on to the the occlusions i want to mention some of the devices out there I'm not trying to get in detail but just to make it reader where you know there's

the baiance catheter from atronics essentially like a little metal drill it wobbles and tries to find the path of least resistance to get through the occlusion the cross or device from bard is a device that is essentially or what

I call is a frakking device they're examples they'll take a little peppermint they'll sort of tap away don't roll the hole peppermint so it's like a fracking device essentially it's a water jet

that's pulse hammering and then but but to be honest I think the most effective method is traditional wire work sorry about that there are multiple you know you're probably aware of just CTO wires multi weighted different gramm wires 12

gram 20 gram 30 gram wires I tend to start low and go high so I'll start with the 12 gram uses supporting micro catheter like a cxi micro catheter a trailblazer and a B cross so to look at here the sheath I've placed a sheet that

goes into the SFA I'm attacking the two occlusions first the what I used is the micro catheter about an 1/8 micro catheter when the supporting my catheters started with a trailblazer down into the crossing the first

occlusion here the first NGO just shows up confirmed that I'm still luminal right I want to state luminal once I've crossed that first I've now gone and attacked the second occlusion across that occlusion so once I've cross that

up confirm that I'm luminal and then the second question is what do you want to do with that there's gonna be a lot of discussions on whether you want Stan's direct me that can be hold hold on debate but I think a couple of things we

can agree we're crossing their courageous we're at the pop if we can minimize standing that region that be beneficial so for after ectomy couple of flavors there's the hawk device which

essentially has a little cutter asymmetrical cutter that allows you to actually shave that plaque and collect that plaque out there's also a horrible out there device that from CSI the dime back it's used to sort of really sort of

like a plaque modifier and softened down that plaque art so in this case I've used this the hawk device the hawk has a little bit of a of a bend in the proximal aspect of the catheter that lets you bias the the device to shape

the plaque so here what I've done you there you can see the the the the the teeth itself so you can tell we're lateral muta Liz or right or left is but it's very hard to see did some what's AP and posterior so usually

what I do is I hop left and right I turned the I about 45 degrees and now to hawk AP posterior I'm again just talking left to right so I can always see where the the the the AP ended so I can always tell without the the teeth

are angioplasty and then here once I'm done Joan nice caliber restored flow restored then we attacked the the common for most enosis and sfa stenosis again having that device be able to to an to direct

that device allows me to avoid sensing at the common femoral the the plaque is resolved from the common femoral I then turn it and then attack the the plaque on the lateral aspect again angioplasty restore flow into the common firm on the

proximal SFA so that was the there's the plaque that you can actually obtain from that Hawk so you're physically removing that that plaque so so that's you know that's the the restoration that flow just just you know I did attack the

posterior tibial I can cross that area I use the diamond back for that balloon did open it up second case is a woman

my last case here you have a 54 year old patient recent case who had head and neck cancer who presents with severe bleeding from a tracheostomy alright for some bizarre reason we had two of these

in like a week all right kind of crazy so here's the CT scan you can see the asymmetry of the soft tissue this is a patient who had had a neck cancer was irradiated and hopefully what you can notice on the

right side of the screen is the the large white circles of contrast which really don't belong there they were considered to be pseudo aneurysms arising from the carotid artery all right that's evidence of a bleed he was

bleeding out of his tracheostomy site so here's a CTA I think the better image is the image on the right side of the screen the sagittal image and you can see the carotid artery coming up from the bottom and you can see that round

circle coming off of the carotid artery you guys see that so here's the angiogram all that stuff that is to the right to the you know kind of posterior to the right of the screen there it doesn't belong there that's just

contrast that's exiting the carotid artery this is a carotid blowout we'll call it okay just that word sounds bad all right so that's bad so another question right what do you want to do here

I think embolization is reasonable but probably not the thing we can do the fastest to present a patient to treat a patient is bleeding out of the tracheostomy site so in this particular case this is a great covered stent case

alright and here's what it looked like after so we can go right up and just literally a cover sent right across the origin of that pseudoaneurysm and address the patient's bleeding alright

here a little bit okay the ellipsis device Avenue medical from California developed by Jeff Howe in Richmond ultrasound imaging only don't need

fluoroscopy everybody in the room like staff they'd off to where lid you advance the needle into the either the very distal cephalic vein or through the actual perforator under ultrasound and once you're there you

follow the tip of the needle keeping it in the center of the lumen of the vein under ultrasound guided down to the point where it's just adjacent to the radial artery and then once you're adjacent to the radial artery this may

take a little bit of torquing of the needle but you know even putting in PICC lines for what 15 years 20 years so it's nothing not more difficult than that which is you know why I tell the fellows do the PICC lines you're not doing the

PICC lines just to do pickle and you're doing them so you can do these kinds of procedures then you puncture the radial artery then you get arterial blood flow you put a wire down and you get a sheath down and you put the device down I'll

show you the device in just a second it's called tissue welding it's an electronic device that creates a anastomosis doesn't really succumb to any problems with vascular wall calcifications usually takes just 30 to

45 minutes I did the last one the other day in 15 minutes and angioplasty the anastomosis immediately following the creation of the fissure with a 5 millimeter 1/8 balloon of your choice here's the device you can see it opens

up there's like a little bit of a window there and so it goes down through the vein it crosses over into the artery you're able to see this under ultrasound you position that window as you see on the right with the artery and wall the

vein artery vein and artery walls between that space and then the debate the device closes down on them then the machine will give you a reading of what the distances you push to the button and you got a fistula and it's very pretty

straightforward then you go ahead and balloon that with a five millimeter balloon to make sure the anastomosis is open and running and that's it then you pull out and you can compress with one finger you know on the vein and here's a

look at the the anatomic and that's office Jilla that it does create you know you don't mobilize there's no surgical trauma patient goes home with a couple of band-aids here's a dissection with ultrasound of the area that you're

working in there on the right you can see the perforator coming down it's sitting over the PRA the right proximal radial artery and that's right where you're going to make your puncture from one vessel into the other and this is

what you're left with on the left of course you see a big surgical scar from a prior creation of probably in the brachiocephalic fistula and on the right you can see the very prominent cephalic vein after fish through the creation

which is getting ready to to be punctured here's the illustration of what you've just done again perforating vein going down towards the radial artery create the fish stool and now you have a brachial artery down radial

artery so you have a radial proximal radial perforating vein fistula I don't know whether it hopefully it goes up the cephalic vein if it goes up the basilic vein you may have to consider doing transpositions or elevation to get that

vein in a position of yeah so that it can't be punctured here's another ultrasound from one of our cases again showing a nice you know red to blue flow of the fistula here's another one you know I have to see these a while you say

wow it's really pretty amazing and what we do is we get velocity measurements at the time of the procedure one week later then at four weeks later and at four weeks if they're not flowing at least 500 to 600 cc's a minute then we'll go

in and do a secondary balloon or something to get things going there's that same patients actually this is our patients arm it's a different patient and you can see the flow map there and when you see that diastolic component

got halfway up the systolic that means you're flowing at about 600 500 to 600 cc's a minute it's a good indication that you've got a you've created a fistula with working potential if you have to re intervene it's a radial

puncture you go right up the the radial artery I'm sure your dad is familiar with doing that for the most part and that goes right across that and ask Tomo system so if you have to dilate the anastomosis to get a larger you're in

good position if you have to go up and redirect flow by embolization of small collaterals nor the brachial veins now you can do that all from the the radius it's nice highway right up into the fistula

and here's the results of the FDA trial

patient female patient who has the sudden onset of upper abdominal pain here's the CT we did all these cases in one day it was crazy it was terrible so so here's a big hematoma a big peritoneal hematoma you

can see it anterior to the right kidney you can see the white blob of contrast right in the middle of the hematoma that's a pseudoaneurysm or even active extravagance um less experienced people would probably say it's active

extravagant I think most of us would prefer that it be called kind of a pseudoaneurysm this active extrapolation would be much more cloudy and spread out this is more constrained and you can see on the

coronal image you get a sense that there's that hematoma same type of problem all right is there more imaging that we can do to figure out the next step again I said earlier earlier in this lecture

that sometimes we use CTA now sometimes a CTA is worthwhile I do find that for a lot of these patients I think we're getting smarter and we're doing CTAs right at the beginning of this whole thing you know when a trauma

patient comes in we're getting CTAs so we can max out the amount of information that we get on the initial diagnostic imaging here's what we're seeing on the CTA and in this particular case I think it's pretty clear that you can see the

pseudoaneurysm arising from what looks like a branch of the superior mesenteric artery so this is just an odd visceral and Jake visceral aneurysm which looks like it probably ruptured I don't have an explanation for it led to a big

hematoma here's what that is and now we're gonna do an angiogram the neat thing is it just perfectly correlated with a conventional angiogram so here's our super mesenteric angiogram all right the supreme mesenteric artery

on the first image to the left is that vessel going downward towards the right side of the screen all those vessels coming off are really just collateral vessels going up to the liver through the gastroduodenal artery again that

left one looks pretty good it's not until you see the delayed image on the right that you see that area of contrast all right so that's the finding that correlates with the CT scan all right here we're able to get in there you put

a micro catheter in that vessel alright the key next step for this patient as I mentioned earlier is the whole concept of front door and back door so here we're technically in the front door the next thing that we do is we put the

catheter past the area of injury and now we embolize right across the injury because remember once you embolize one thing flow is gonna change we screw it up body the body wants to preserve its flow if we block flow

somewhere the body's gonna reroute blood to get to where we blocked it so we want to think ahead and we want to say okay we're blocking this vessel how's the body going to react and let's let's get in the way of that happening that's what

we did here so we saw the pathology we went past it we embolized all across the pathology and boom now we don't have anymore bleeding and the likelihood of recurrence is gonna be very low for that patient because we went all the way

across the abnormality and I think from

quick I did want to mention t-carr briefly and try to get you guys closer to back on time this is a hybrid procedure this is combining the surgical procedure we talked about first and carotid stenting it takes combined

carotid exposure at the base of the clavicle or just above the clavicle and reverses blood flow just like we talked about but tastes slightly different technique or approach to doing this and then you put the stent in from a drug

carotid access here's the components of the device right up by the neck there is where the incision is made just above the clavicle and you have this sheet that's about eight French in size that only goes in about us to 2 cm or 1 and a

half cm overall into the vessel and then that sheath is sutured to the the chest wall and then it's got a side arm that goes what's labeled number six here is this flow reversal urn enroute neuroprotection kit it reverses the

blood flow and then you get a femoral sheath in the vein right in the common femoral vein and you reverse the blood flow so this is a case a picture from our institution up on the right is the patient's neck and that's the carotid

exposure and the initial sheath is in place so the sidearm of that sheath is the enroute protection system which is going up up at the top of the image there we're gonna back bleed that let that sidearm of that sheath continue to

bleed up to the very top and then connect that to the common femoral venous sheet that we have in place there's a stepwise of that and then ultimately what we see at the end of the procedure is that filter inside that

little canister can be interrogated after and you can see the debris this is in the box D here on the bottom left the debris that we captured during the flow reversal and this is a what we call a passive and then active flow reversal

system so once the system is in place the direct exposure carotid sheath in place the flow controller and AV shunt in place you see the direction of blood flow so now all that blood flow in that common carotid artery is going reverse

direction and so when you place a sheath or wire and and ultimately through that sheath up by the carotid artery there's no risk for distal embolization because everything is flowing in Reverse here's a couple

case examples ferns from our institution this is a patient who had a symptomatic critical greater than 90% stenosis has tandems to nose he's so one proximal at the origin and one a little bit more distal we you can see the little

retractors down at the base of the image there in the sheath that's essentially the extent of the sheath from the bottom of that image into the vessel only about a cm or two post angioplasty instant patient tolerated that quite well here's

another 71 year-old asymptomatic patient greater than 90% stenosis pretty calcified lesion a little more extensive than maybe with the CT shows there's the angiography and then ultimately a post stent placement using the embolic

protection device and overall the trials have shown good good safety met profile overall compared to carotid surgery so it's a minimum minimal exposure not nearly as large the risk of stroke is less because you're not mucking around

up there you're using the best of a low profile system with flow reversal albeit with a mini surgical exposure overall we've actually have an abstract or post trip this year's meeting this is just a snapshot of that you can check it out

this is our one year experience we've had comparable low complication rates overall in our experience so in summary

to talk about cryoablation which is very commonly used in a number of organs it can essentially be used anywhere in my opinion with cryoablation as many of you know the different idea is that you have a probe and it creates this ice ball and

that's what's killing the tissues rather than heating the tissue when they first came out with cryoablation they had these really large probes and that really limited what we could do well with technology obviously those probe

size decreased and we were able to do better ablations and safer oblations in patients so it really took off at that point and the general goal once again is to decrease the temperature to about minus 20 degrees Celsius and in doing so

you kill the tissue and we'll talk about the mechanism of how that works the cold spreads Bible directly molecular transfer right so you're starting to cool around the probe and that will propagate to the surrounding tissue

unlike our FA or microwave as the ice ball grows it doesn't impede further ice ball growth right you can continue to build on that ice ball as you increase the amount of argon infused in the increase the number of probes so that's

beneficial and that you can get a massive ablation depending on how many probes you want to place well talk a little bit of how it works so it works by what's called the joule-thompson effect idea here is if any of you've

done cry before you know you have to drag those huge tanks into the room and it just runs through all gone like nothing so when we first started doing cryoablation you had to have an all gone tank and a helium tank they've gone away

with the helium and now you really just need the argon tank which is really nice and that you don't have to drag those tanks around and they're working on actually doing with nitrogen but that hasn't come to fruition yet so the idea

is that you take a high-pressure gas right so it's in the tank it's pressurized it gets run through the center of the probe and then as it comes out the tip will not out the tip of the probe and within

the tip of the probe it goes to low pressure and that change in pressure allows the temperature of the probe tip to cool right and so if you're using argon or oxygen or nitrogen that'll cool if you're using helium it'll actually

heat the tissues and so that's why we used to have argon and helium to be able to to freeze and then actively Thor so as I mentioned the argon comes from a pressurized tank you have this dual chamber probe that allows the gas to

expand and as it expanded pools heat from the surrounding tissues so as many

ablating things in the bones well musculoskeletal blasian we're fortunate within our practice that we have a doctor councilman Rochester who's

a probably one of the biggest world's experts on this and these are his cases that he shared but you can see when you have small little lesions and bones that are painful you can place probes in them and you freeze them the tumor dies and

musculoskeletal things remain intact what about when you have cases like this where there's a fracture going through the iliac bone on the left with an infiltrate of malignancy well you can cryo blade it and what's cool about is

you can using CT guidance do percutaneous cannulated pins and screws and a cement o plasti ver bladed cavity and when you're done the patient who initially couldn't walk now can and whose pain scale went down to one so I

think that's that's very important to realize the potential of image-guided medicine this is something that previously would have had to been done in the orthopedic lab so you know I think this is extending options where

otherwise it would have been difficult same thing applies to the spine you can ablate and fill them with cement so

designed a u.s. clinical study we got an investigational device exemption

actually Julie's our clinical research coordinator for this study and these are the inclusion exclusion criteria we basically excluded patients who have rheumatoid arthritis previous surgery and you had to have moderate or severe

pain so greater than 50 means basically greater than 5 out of 10 on a pain scale we use a pain scale of 0 to 100 because it allows you to delineate pain a little bit better and you had to be refractory to something so you had to fail

medications injections radiofrequency ablation you had to fail some other treatment we followed these patients for 6 months and we got x-rays and MRIs before and then we got MRIs at one month to assess for if there was any

non-target embolization likes a bone infarct after this procedure these are the clinical scales we use to assess are not really so important as much as it is we're trying to track pain and we're trying to check disability so one is the

VA s or visual analog score and on the right is the whoa max scale so patients fill this out you can assess how disabled they are from their knee pain it assesses their function their stiffness and their pain

it's a little bit limiting because of course most patients have bilateral knee pain so in trying to assess someone's function and you've improved one knee sometimes them walking up a flight of stairs may not improve significantly but

their pain may improve significantly in that knee when we did our patients these were the baseline demographics in our patients the average age was 65 and you see here the average BMI in our patients is 35 so this is on board or class 1

class 2 obesity if you look at the Japanese study the BMI in that patient that doctor okano had published the average BMI and their patient population was 25 so it gives you a big difference in the patient population we're treating

and that may impact the results how do we actually do the procedure so we palpate the knee and we feel for where the pain is so that's why we have these blue circles on there so we basically palpate the knee and figure

out is the pain medial lateral superior inferior and then we target those two Nicollet arteries and as depicted on this image there are basically 6 to Nicollet arteries that we look for 3 on the medial side 3 on the lateral side

once we know where they have pain we only go there so we're not going to treat the whole knee so people come in and say my home knee hurts they're not really going to be a good candidate for this procedure you want focal synovitis

or inflammation which is what we're looking for and most people have medial and Lee pain but there are a small subset of patients of lateral pain so this is an example patient from our study says patient had an MRI beforehand

and you can see on this t1-weighted image that increased area of enhancement which is the area of synovial thickening you actually see this on MRI beforehand and there it is located over the lateral aspect of the knee on the axial image

and so what we're doing sorry in the medial aspect of the knee so what we're doing here on the angiogram is and you solve these leg angiograms where everyone doesn't really care about these you Nicollet arteries they're really

important when you have SMA or popliteal occlusive disease because they serve as a collateral source but otherwise and people have arthritis they can be a real pain and the pain in the knee if you will so this is a this is the superior

medial geniculate artery and always drapes over the femoral condyle and you'll see here on this image you don't really see very much but once we get into the vessel look at this it almost looks like a small about a cellular

carcinoma like when you're in the liver you get this tumor type blush vascularity that's what we're looking for that corresponds to the patient's area of pain and then after embolization this is what it looks like takes a very

small embolic we're using maybe point four two point six sometimes one CC at most of dilute embolic that we're injecting this is another case again before and after if you look here on the right and then

on the left you don't really see much until you select the vessel out once you get into that super medial vessel you can see how much enhancement there is so in our clinical study of twenty patients this is what we did you'll see on the

bottom here we used embassy and 75 micron in nine patients and eleven eleven patients got a hundred micron and I'll explain why we upsized our particles so initially we wanted to go very small because that's where dr. o

Cano had done in Japan but then we wanted to actually up size our particles and I'll explain this here in our complications so like all clinical studies the purpose of doing really good clinical research is because this is

early and we don't know if they're going to be complications and it's always fun when you're the first one to figure it out and you tell patients I don't really know what's gonna happen and this is what happens so thirteen patients had

this kind of skin discoloration over their knee now we knew this because we've been doing the embolization for about ten years in bleeding patients not necessarily arthritic patients so we had seen this before but none of these

patients in this clinical study went on to have any alteration of the skin and it resolved in all patients there was some minor side effects from basically medications and one small groin hematoma but there were two patients who

developed plantar numbness over their great toe so under their great toe basically the medial distribution of their tibial nerve they ended up getting plantar numbness and this is believed at least in our experience to probably be

related to non-target embolization to the tibial nerve the tibial nerve probably gets its blood supply from many of these Jamaican arteries so we decided after having these two cases one at our institution and one at University of

North Carolina Chapel Hill that we would then basically upsize our particles to 100 micron and we have not seen that and we're doing a second clinical study and I'm not seeing that he's either we had about a 70% reduction in pain so if you

look at our visual analog score out to six months and if you look at our disability it actually paralleled this exactly which is pretty impressive considering mostly patients had bilateral knee pain so out to six months

very good results 90% of patients were responders so two out of our twenty patients did not really respond one patient didn't respond at his one month follow-up but did wrist that is three and six so I still

consider them a clinical failure because we expect these patients to respond by one month here's just an example of a baseline MRI before and after and you can see all that joint effusion there the white that decreases just even after

a month how much it decreases and we looked at this in terms of synovial thickness and distension and even on MRI you can objectively count calculate synovitis scores and we calculated that they actually statistically decreased

this is another patient on the left the image shows diffuse white enhancement if you will of the synovium of the lining on the right it shows the fluid this is an image just of embolization and I show this image because it's really shocking

and this is actually one of our nurses who's enrolled in the clinical study is this is before this is all we did we embolized the medial aspect of the knee this is one month later 30 days in fact somebody just asked me this when I was

in the booth over at the meeting across the street and basically I said listen I don't know why this happened so quickly I have no idea we didn't tap her knee we didn't do anything else if you look at this premium post it's pretty dramatic

so clearly there's an inflammatory process that we are arresting or stopping in such a short period of time so is there a future for this I don't know it may just we may just fall down and find out that there really is in a

great future but so far we know it's at least technically successful it's the results are positive in the short term long term we're not so sure yet we do need to better understand these risks and I think in my opinion in the long

term it'll probably really really good for this 40 to 65 year old patient population who's not yet ready for knee replacement surgery this is the algorithm for our clinical study which were almost done enrolling right now

it's a randomized control study against placebo so it's two to one randomization which means one third of the patients actually get a sham procedure so we do an angiogram on their leg they're asleep they have no idea for embolizing there -

Nicola arteries are not we wake them up and they get off the table and we follow them up if they're no better they're allowed to cross over and get the treatment the other 2/3 of the patient actually get the treatment and they

don't know either if they got the treatment and then we follow these patients when we assess if you if they have improvement all pain mediated procedures must undergo sham controlled studies because pain is so right in it's

so intuitive to just yourself so you can't really if there's a placebo effect so this is why pussy bow control studies are very important I believe we have one more patient left to enroll in this clinical

study and then we should be done with that so I'll switch gears really quick

helpful and you know many of us use this on the table at the time of the procedure we also look at our own images because it reports are not all that helpful and what you're looking for I don't know duplex ultrasound is what is

the vessel wall look like is it narrowed is it patent are there are there large collateral so you're going to need a lookout for or what's the velocity of flow because as you know as you know you put your

finger over the end of a of a garden hose it's going to increase the velocity of the water that you're shooting at somebody and the flow direction and quality can also be detected so color Doppler imaging often changes from this

kind of smooth the uniform color with laminar flow on the on the right side to one of multi-directional flow with turbulence you'll see colored multiple different colors in the same image spectral Doppler waveforms are also

obtained with with duplex ultrasound so what you're looking for is this is the the picture equivalents of marks noises from earlier which is a triphasic waveform see that the flow goes above the line and then goes back below the

line and then comes you can wholly state that it comes back above the line here that would suggest that it was triphasic or normal and then these often just go above the line and they never go back below the line and these patients if

they're if you're looking at the ultrasound below the level and destruction so we're looking for a return from the image on the right to the image on the left we have specific number criteria that we use as a

determination of whether one we've been successful the numbers are not that important but the ant vanish is a duplex are that it's low-cost and it's highly sensitive but it it's time-consuming and depending on who the operators are that

are actually taking the images and who are the readers are you may or may not find them that helpful and it's less accurate for determining if the vessels completely occluded because they may just not have seen it they may have

missed it so it's operator dependent several papers suggest that we should be this should be our first line imaging study for following up patients after we do an intervention particularly angioplasty alone and if the initial

follow-up is normal we can usually push them out to just clinical follow-up and making sure they have a pulse exam if patients have an abnormal finding then we usually bring them back sooner and get a repeat ultrasound at two to three

months CT a very sensitive and specific

advantages of radiofrequency ablation or that there's the most research on this

right so if you look up ablation research there's a whole lot of data and research on this as it's been the longest studied so that's always beneficial when you're trying to convince people that they should get an

ablation it's cheap right although some of the problem with that is a lot of manufacturers aren't making some of the devices anymore so to get replacement probes and that sort thing is difficult but it is certainly much cheaper than

the other modalities its gentler than microwave right so it's a slower increase in temperature and you can control it the disadvantages as we mention right so the ablation zone this is probably the worst part about

radiofrequency ablation is that the ablation zone is unpredictable right now we're trying to go towards this idea where we can predict the exact size of the ablation and really with RFA it was more experience related right so if

someone I've been doing them for 20 they can have a good idea how it's gonna it's gonna blade but that ablation zone is very unpredictable it's very tissue dependent right so if you have cirrhosis and the liver is

really scarred down you're gonna get a different ablation as to someone who has a normal appearing liver you have the heatsink effect which as I mentioned can be used as an advantage but usually as a disadvantage and then large large burns

are difficult right so anything greater than 4 centimeters even that is difficult to achieve with RFA it is possible to get skin burns at the grounding pad so if you're gonna do RFA make sure that the patient doesn't have

a hip prosthesis for instance and make sure you know it sometimes patients get sweat underneath the the pads and that can increase skin burns and those pads so that's one of another downside of a radiofrequency ablation so we'll move on

different applications renal ablation is very common when do we use it

high surgical risk patients primary metastatic lesions some folks are actually refused surgery nowadays and saying I'll have a one centimeter reno lesion actually want this in lieu of surgery people have

familial syndromes they're prone to getting a renal cancer again so we're trying to preserve renal tissue it is the most renal parenchymal sparing modality and obviously have a single kidney and a lot of these are found

incidentally when they're getting a CT scan for something else here's a very sizable one the patient that has a cardiomyopathy can see how big the heart is so it's you know seven centimeter lesion off of the left to superior pole

against the spleen this patient wouldn't have tolerated bleeding very much so we went ahead and embolized it beforehand using alcohol in the pide all in a coil and this is what it looks like when you have all those individual ice probes all

set up within the lesion and you can see the ice forming around I don't know how well it projects but in real time you can determine if you've developed your margin we do encompass little bit of spleen with that and you can see here

that you have a faint rim surrounding that lesion right next to the spleen and that's the necrotic fat that's how you know that you got it all and just this ablation alone caused a very reactive pleural

effusion that you can see up on the CT over there so imagine how this patient would have tolerated surgery pulmonary

blasian it's well tolerated and folks with advanced pulmonary disease there's a prospective trial that showed that

there are pulmonary function does not really change after an ablation but the important part here is a lot of these folks who are not candidates for surgical resection have bad hearts a bad coronary disease and bad lungs to where

a lot of times that's actually their biggest risk not their small little lung cancer and you can see these two lines here the this is someone who dr. du Puy studied ablation and what happens if you recur and how your survival matches that

and turns out that if you recur and in if you don't actually a lot of times this file is very similar because these folks are such high risk for mortality outside or even their cancer so patient selection is really important for this

where do we use it primary metastatic lesions essentially once we feel that someone is not a good surgical candidate and they have maintained pulmonary function they have a reasonable chance for surviving a long

time we'll convert them to being an ablation candidate here's an example of a young woman who had a metastatic colorectal met that was treated with SPRT and it continued to grow and was avid so you can see the little nodule

and then the lower lobe and we paste the placement prone and we'd Vance a cryo plugs in this case of microwave probe into it and you turn off about three to five minutes and it's usually sufficient to burn it it cavitate s-- afterwards

which is expected but if you follow it over time the lesion looks like this and you say okay fine did it even work but if you do a PET scan you'll see that there's no actually activity in there and that's usually pretty definitive for

those small lesions like that about three centimeters is the most that will treat in a lot of the most attic patients but you can certainly go a little bit larger here's her follow-up actually two years

that had no recurrence so what do you do when you have something like this so this is encasing the entire left upper lobe this patient underwent radiation therapy had a low area of residual activity we followed it and it turns out

that ended up being positive on a biopsy for additional cancer so now we're playing cleanup which is that Salvage I mentioned earlier we actually fuse the PET scan with the on table procedural CT so we know which part of all that

consolidated lung to target we place our probes and this is what looks like afterwards it's a big hole this is what happens when you microwave a blade previously radiated tissue having said that this

was a young patient who had no other options and this is the only side of disease this is probably an okay complication for that patient to undergo so if you follow up with a PET scan three months later there's no residual

activity and that patient actually never recurred at that site so what about

good afternoon everyone so I have the big task about talk about IR in Algeria and UAE and couple words about the past meeting so my name is Hoshino bada I'm intervention ideologies I joined the unit in Abu Dhabi almost 5 years ago so I think everybody's familiar now with

the African continent so Algeria between Morocco and Tunisia so it's a bit difficult or bother the iron algea because it's a very very early stage and these couple numbers give you an idea about the the landscape

readiness came health care system over there we have about 850 CT scanners 250 MRI for about 144 hundred one thousand four hundred forty thousand radiologists if you compare between Morocco they have almost 700 and 800 in Tunisia and about

2700 radiographers but only twelve IR people two of them performing your IR as well so one of the main issue it is not as social IR curriculum over there and there's not even a chapter of any intervention society that can help to

promote as a platform to promote the IR program however on the other hand they have a very dynamic and very active society of radiology and actually they are performing a really lot of work by doing a lot of meetings worktop hands-on

workshop all over the year all over the year absolutely and in the last four or five years they also introduced IR in their in their meetings and so exposed to the the young residents and and radiologists it triggers as some some

momentum about IR over there and so some of them went to in Europe together had trained fellowship and they came back to our Jaso even there's a small number of IR over there they are only fully trained in Europe with a with a good

quality so but of course the number is very small so a lack of IR that means some some people have to do the work and the classic thing happens like the Ignacio is going to perform some of the procedure which means biopsies drainages

or the video intervention and some somehow some ablation therapies in very limited centers and if you look at the vascular access or the Lions barakatuh performed by almost everybody radiologists cardiologists surgeons even

anesthesiologist there's not enough people to do in a foursome it's ornery Rogers doing the first time it's the only area when it's 100% I would say imaging people is definitely regarding Western intervention from diagnostic

tool to biopsy to intervention so if you look at the vascular interventional quite similar what well said in in in Egypt so the vascular stuff is doing by IR however all the outer condition that performs swiftly by vascular surgeon but

nowadays summer some changes because they are facing some issues essentially though they do send graft they don't have to do they don't know how to deal with the unduly so there's more and more kind of through there I'll reconsider

the need for collaboration with IR and they start to really have some some bridge all together to fulfill the complication and issue they might and control in their practice so the only optimistic things now in Algeria is that

there is definitely a big Werner's at the level of the old age about creating a really implementing a training program for IR and the actually they are trying really to to initiate and start that so working progress that the Society of

international urology over there so there is hope about the future in terms of implementing this type of program and before moving into the UAE just a small comment I know you do a co2 injection in your daily practice just give you an

idea about that so this was pioneered by a giant team in the late 60s and early 70s so this is this work was performed a couple years before the work of Hawkins actually Hawkins always reference the Algerian team about about that so now we

move to the UAE

so why staging important well when you go to treat someone if I tell you I have a lollipop shaped tumor and you make a lollipop shape ablation zone over it you have to make sure that it's actually a lollipop shaped to begin with so here's

a patient I was asked to ablate at the bottom corner we had a CT scan that showed pretty nice to confined lesion looked a little regular so we got an MRI the MRI shows that white signal that's around there then hyperintensity that's

abnormal and so when we did an angiogram you can see that this is an infiltrate of hepatocellular carcinoma so had I done an ablation right over that center-of-mass consistent with what we saw on the CT it

wouldn't be an ablation failure the blasian was doing its job we just wouldn't have applied it to where the tumor actually was so let's talk about

and you can see on this t1-weighted image that increased area of enhancement which is the area of synovial thickening you actually see this on MRI beforehand and there it is located over the lateral aspect of the knee on the axial image

and so what we're doing sorry in the medial aspect of the knee so what we're doing here on the angiogram is and you solve these leg angiograms where everyone doesn't really care about these Janicki lit arteries they're really

important when you have sfa or popliteal occlusive disease because they serve as a collateral source but otherwise and people have arthritis they can be a real pain and pain in the knee if you will so this is a this is the superior medial

genicular artery it always drapes over the femoral condyle and you'll see here on this image you don't really see very much once we get into the vessel look at this it almost looks like a small about a cellular carcinoma like when you're in

the liver you get this tumor type blush vascularity that's what we're looking for that corresponds to the patient's area of pain and then after embolization this is what it looks like takes a very small amount

of embolic we're using maybe 0.4 2.6 sometimes 1 CC at most of dilute embolic that we're injecting this is another case again before and after if you look here on the right and then on the left you don't really see much until you

select the vessel out once you get into that super medial vessel you can see how much enhancement there is so in our clinical study of 20 patients this is what we did you'll see on the bottom here we used embassy and 75 micron in 9

patients and 1111 patients got a 100 micron and I'll explain why we upsized our particles so initially we wanted to go very small because that's what dr. o Cano had done in Japan but then we wanted to actually up size our particles

and I'll explain this here in our complications so like all clinical studies the purpose of doing really good clinical research is because this is early and we don't know if they're going to be complications and it's always fun

when you're the first one to figure it out and you tell patients I don't really know what's gonna happen and this is what happens so 13 patients had this kind of skin discoloration over their knee now we knew this because we've been

doing knee embolization for about 10 years in bleeding patients not necessarily arthritic patients so we had seen this before but none of these patients in this clinical study went on to have any alteration of the skin and

it resolved in all patients there was some minor side effects from basically medications and one small groin hematoma but there were two patients who developed plantar numbness over their great toe so under their great toe

basically in the medial distribution of their tibial nerve they ended up getting plantar numbness and this is believed at least in our experience to probably be related to non-target embolization to the tibial nerve the tibial nerve

probably gets its blood supply from many of these generic arteries so we decided

so my Xtreme ir case is a TVR with on a patient with a type you tie section and then we use laser to find a straight the dissection flap and I just want to before I start I just want to give a big shout-out to my attending dr. Kasia and Rudy pump Adi on our IR resident Rudy

put these really cool illustrations together as you will see on these upcoming slides and dr. Kaja he did this case and basically it helps me with everything so since your old male patient presenting with history of

chronic type UTI section um he was medically managed with and I'll G Saxena antihypertensives and then he came into the ER a couple months later and it was complaining of severe back and chest pain so a CTA was

performed and and they found that there was a significant growth in the descending thoracic aorta and so we have a couple images here we have a 3d reconstruction of the aorta as well as the sagittal image of that CTA and does

anyone notice anything about this 3d on aorta no so this patient has a variant he has a bull vine arch actually so the left common carotid is coming off the right you nominate um but vessel the arteries so it's nice for us when we're

placing that and negraph we have more more of a landing zone so we're not covering any of important structures other than the less left subclavian artery and so we're the two arrow heads are on the sagittal image you will see

that there's reentry tears so if you look at the 3d image so the dissection is that line right in the middle and so it's starting at the origin of near the LSA and ending at the level of the celiac artery okay so we obtained right

and left common femoral access and you obtain left brachial access as well and the reason for left particular access is once we get our enter graph gen we're going to go ahead and I'm pass the wire through and a laser through and find us

to find a straight through that under graft so you can have flow but I will talk about that later so we put a twenty French dry seal sheath and the right groin and in the left groin we had a 8 by 45

she's and that was basically to accommodate IVA so they can kind of get a feel for what we're doing it just like another resource we have so we have two IVs images here the one on the left with the yellow arrow basically is just

showing us that thickened dissection flap and the Ibis on the right is the love of the celiac artery so the celiac artery is where that green arrow is pointing to and the white arrow head is basically just showing us that reentry

tear at that level and so through the right through the right the sheet on the right hand side the 20 French try seal sheets we placed the 7 by a 55 Aptus on steerable tour tour guide sheath so that basically can angle up to 180 degrees so

we place that up to sheath in the true lumen of the aorta and pointing towards the false lumen and then I just put some pictures up of what a dissection looks like I don't know if a lot of people a lot of you guys on do dissection their

frustrations I mean your practice but I just thought it would be nice to show and so once we have the Aptus sheep up in the true lumen and have it pointed towards on the false women we confirmed with the eye this just to make sure

we're on the right spot and we're not we're not going to harm any other structures when we laser so once we have that up we use laser to kind of poke a hole and fenestrated create that's here and once we did that we dragged while

the laser was on we dragged the baptists sheath down 4 centimeters and created a large terror so the whole goal is to open up that dissection so we could eventually place that under graph so once and that there's a florist got the

image of ibis and apt the Aptus sheath and all that and so we created a large tiara and then what we did was we passed the 18 wire into the false live and we angioplasty with the 14 by 4 centimeter balloon and as you can see that there is

some waste on that balloon and then eventually it dilated up to you know now I'm gonna burst rate which was 18 and so that Ibis is basically showing us that's here that we just made in our dissection flap

okay am I not there we go okay so once we angioplasty be repeated the same thing so we put the laser back up get a small tear right underneath large penetrations here that we just said and then we angioplasty it so once we

angioplasty we connected that top tier and bottom tear together we opened it all up and we angioplasty it again after that so once that I mean go back so once the angioplasty so right underneath that big tear that we just made so between

the tear that we just made and the re-entry is here at the level of a celiac you still have that little piece of a dissection flap that we still need to open to place our under graft so once we did that once we angioplasty through

the right groin we passed up a glide catheter and the true lumen and pointed it towards the false women and through on the tear that we just made we passed the v18 wire and through the left groin we went up with a 20 millimeter loop

snare and so we grabbed the the 18 wire and so that loop snare went and that reentry tear and like into the false lumen so our whole point is to get through and through access with that wire so we can use as a wire cutter to

cut the remaining flaps so that's what we did so we we grabbed that snare we grab that v18 with the snare we pulled it out of the left groin and we obtained through and through access okay so you're just ripping it down yeah

basically it's like it she goes somewhere yeah yeah you got it yeah that's exact don't ask a question to what you don't want the answer so basically that's what we did so once we got through into access we advanced both

sheets and we kind of like pull down to to cut the remaining flap so once we did that we basically had everything open so we were ready to place our under graft so we did angiography and then we ended up

deploying the descent and then so once we would deploy the stent we basically covered that LSA the left subclavian artery so that's exactly why we got brachial access so we pass the wire through and got to the origin of the LSA

and then we ended up putting the laser down and then we turn the laser on poked a hole and so now we have this hole and this endograft so once we did that we angioplasty it and then we deploy the stents okay and so now we have a diagram

of the pates and LSA following stenting so we sent in the aorta and where the dissection was and then resented the LSA so we have nice nice flow the REC lab donal angiogram basically is just demonstrating feeling of the celiac in

superior mesenteric artery as you can see in that middle image distally so one of our missions that Rudy made which is pretty awesome so illustration of fenestrated t-bar with LSA sensing and adequate just so Co following the

dissection flap that we usually there's open so BAM there you go so that's Rudy and I in the middle my one of my co-workers Kevin and when my mentor is dr. Kaja dr. Marley and myself so thank you hi dr. Kasia thanks for joining

so my name is Paul I'm one of the nurse practitioners from UCI Irvine healthcare and what am i one of our minerals in there is basically working on patients for consultations doing the patient rounds writing notes ordering labs etc we also have several clinics that we run

at UCI Medical Center involving patients needing consultations for Libra direct therapies ablations and so forth and one of the more recent clinic that we started running is basically treating patients with BPH and so what we would

know inspiration is basically treating and regarding their symptoms and the procedures pretty much called a prostate artery embolization so the main purpose of this patient excuse me the main purpose of this

topics is basically to provide the general information of what the procedures are about illustrating indications risk and to hopefully help our nursing staff to better take care of these patients sorry so first and

foremost I just wanted to thank my team UC Irvine for allowing me to take some time off of work and enjoying Austin and its many food and object and and allowing me to speak to you guys a little bit about prostate ammo on our

pitchers basically you can't I don't know laser printer but our physicians dr. Karen Nelson she's one of our chief of IR dr. Dan through Fernando dr. Nadine a bitch day and dr. James Castro thesis

he's got daughter Kat Reese is our main doctor that does most of our process embolization our excellent iron nursing team and of course my fellow nurse practitioners who is holding the fort back home Pamela and Takara and watch

and Lou sorry but so our objectives for discussions basically to illustrate the indications and benefits of prostate artery embolization we're going to go over the side effects and risk complications associated with this

procedure and also recognize the value of nursing care going starting from the workup leading to the proper process in trot process and post procedure care sort of a brief outline of what we're gonna be

talking about we're just gonna go over the basic fundamentals of BPH as well as the treatment for PAE and the second portion of this lecture is going over how we walk patients up in clinic what we tell patients and we're gonna go

through the proper care and drop care ask well ask the post-op care and we're going to go through a couple of cases in there it's just to describe to you guys how we care for these special population

microwave as I mentioned the reason people are switching to microwave is

that it's a very predictable burn right a lot of the companies are coming out with software that will give you an exact definition of what the size of the ablation is going to be like and that's very reassuring for the physician if

they're gonna put the probe direct it at some sort of structure they don't want to injure having an exact prediction of what that's gonna look like is very very reassuring so that's why a lot of people are going towards microwave it's very

quick there's no grounding pad issue there's no charring there's no heat sink it's ten minutes essentially the disadvantages is it's a hammer right so when you put it in you

turn it on you're getting a powerful burn so if you if you've got it somewhere wrong like it's up against the diaphragm or something like that you are gonna burn that structure so you just have to be careful with that and once

again the main property there is if you point the probe towards the structure you don't want to damage whatever it is you're unlikely to damage that structure because it will not propagate beyond the

we're going probes I think many of you have used our FA there's all sorts of different probes right so the most common well one of the most common ones is a probe like a Levine probe and what it does essentially is it increases the

number of tines so you put the probe in and you deploy these tines and it increases your ablation size a lot of companies went towards just a single probe and they infuse saline through the probe which will then decrease the rate

at which the temperature increases so that you get a consistent slow increase in temperature to prevent impedance other probes will actually infuse saline into the tissues so that it propagates the ablation better and then finally

there's by polar probes where you put two probes in next to one another and the the ablation occurs just between the two probes and so that's a very controlled ablation that's the most commonly what you see when you do the

spine augmentation procedures with the osteo cool system or whatever system you're using that's the bipolar probe approach so as I mentioned the

about massive PE so let's remember this slide 25 to 65 percent mortality what do we do with this what's our goal what's

our role as interventionalists here well we need to rescue these patients from death you know this it's a coin flip that they're going to die we need to really that there's only one job we have is to save this person's life get them

out of that vicious cycle get more blood into the left ventricle and get their systemic blood pressure up what are our tools systemic thrombolysis at the top catherine directed therapy at the right and surgical level that what

unblocked me at the left as I said before the easiest thing to do is put an IV in and give systemic thrombolysis but what's interesting is it's very much underused so this is a study from Paul Stein he looked at the National

inpatient sample database and he found that patients that got thrombolytic therapy with hypotension and this is all based on icd-10 coding actually had a better outcome than those who didn't we have several other studies that support

this but you look at this and it seems like our use of thrombolytics and massive PE is going down and I think into the for whatever reason that that the specter of bleeding is really on people's minds and and for and we're not

using systemic thrombolysis as often as we should that being said there are cases in which thrombolytics are contraindicated or in which they fail and that opens the door for these other therapies surgical unblocked demand

catheter active therapy surgical unblocked mean really does have a role here I'm not going to speak about it because I'm an interventionist but we can't forget that so catheter directed therapy all sorts

of potential options you got the angio vac device over here you've got the penumbra cat 8 device here you've got an infusion catheter both here and here you've got the cleaner device I haven't pictured the inari float

Reaver which is a great new device that's entered the market as well my message to you is that you can throw the kitchen sink at these patients whatever it takes to open up a channel and get blood to the left ventricle you can do

now that being said there is the angio jet which has a blackbox warning in the pulmonary artery I will never use it because I'm not used to using it but you talk to Alan Matsumoto Zieve Haskell these guys have a lot of experience with

the androgen and PE they know how to use it but I would say though they're the only two people that I know that should use that device because it is associated with increased death within the setting of PE we don't really know you know with

great precision why that happens but theoretically what that causes is a release of adenosine can cause bradycardia bradycardia and massive p/e they just don't mix well so

and then one more example just to sort of illustrate the idea of a heat sink or

a cold sink right so this patient has a mass in their left adrenal gland right next to the aorta it's just anterior to the kidneys so the problem here is if you put a microwave ablation probe right next to the aorta you're likely to burn

the aorta and if you want to point the microwave ablation probe directly at the aorta well there isn't really a good window for that right you would have to go through the kidney you'll go through bowel and on route to getting there so

really I elected to do cryoablation right so that's the mass that's the aorta so you're obviously worried about injuring any order you place two probes into the lesion they obviously are streaking us out right now but that's

the aorta right there so we are four millimeters away from the aorta with these two probes you would think you'd be concerned about damaging it but using that cold sink effect you can see how the ice boss actually carves around the

aorta so you can get a really nice ablation on to that structure with that Waring that you're damaging the aorta or any nearby big vascular structure now that doesn't happen with pancreas if you freeze into pancreas you're going to get

a pancreatitis and if you freeze into bowel your bowel is going to have a perforation so that really just is with blood vessels that you can do that

talk here with something that's new on the horizon believe it or not it was actually on the horizon 20 years ago and then it went away because there were a lot of patients that were treated with a

lot of complications and it's making a resurgence and this is balloon pulmonary angioplasty or BPA for short so this is an intervention which may be feasible in non-operative candidates so I mentioned to the Jamison classification earlier

type 1 and type 2 disease should be treated with surgery again it should be treated is curative but patients with type 2 and a half or 3 disease can be treated with balloon pulmonary angioplasty in the right in the right

frame which means that a surgeon has said I cannot operate on this a medical doctor has said boy they're not going to get better with their medicine let's try something else well this is that something else and that's what involves

everyone in this room so this is these are usually staged interventions with potentially high radiation and contrast dose if you think about it it's like Venis recan and a pulmonary AVM all-in-one so it's a potentially a long

complex procedure with a lot of contrast and a lot of radiation but it can provide a lot of benefit to these patients I'm going to talk about the comp potential complications at the end which is one reason why not

everyone should do these all the time so this is a pulmonary angiogram from the literature when you're injecting a selective pulmonary artery you can see that this patient has multiple stenosis there's no real good flow there the

vessels look shriveled up like I mentioned to you before you can get a balloon across it and balloon the areas and then you can see afterwards so the image a on the left is before an image D is afterwards believe it or not this are

in the most experienced hands because the most experienced hands are for palm the BP AR in Japan they do hundreds of cases of these a year at each hospital I've personally only done five so but this is a something that I'm very

interested in and you can see how how much benefit it has for that patient another way you can see these are the webs and the bands that I mentioned to you earlier so what's interesting is that if you look on the first set of

images on the top and the images on the bottom those are the same patients it's the same view before top rows before and the bottom rows after balloon pulmonary angioplasty so the first image is a pulmonary angiogram where if you kind of

see this there's there's some area areas of haziness those are the webs and bands the image on the the middle is the blown-up views and you can see those areas and then the image on the right is intravascular ultrasound which I use

every day in my practice it's a catheter with an ultrasound on it and when you look at it on the top image image see you can see a lot of thrombus you're actually not seeing flow and on image F on the bottom you're seeing red which is

the blood flow so these patients can actually improve the luminal diameter bye-bye ballooning them you can treat occlusions again image on the left shows you a pulmonary artery with a basically an occlusion proximally and then after

you reek analyze it and balloon it you can see that they can get much more

they travel together so that's what leads to the increased pain and sensitivity so in the knee there have been studies like 2015 we published that study on 13 patients with 24 month follow-up for knee embolization for

bleeding which you may have seen very commonly in your institution but dr. Okun Oh in 2015 published that article on the bottom left 14 patients where he did embolization in the knee for people with arthritis he actually used an

antibiotic not imposing EMBO sphere and any other particle he did use embolus for in a couple patients sorry EMBO zine in a couple of patients but mainly used in antibiotic so many of you know if antibiotics are like crystalline

substances they're like salt so you can't inject them in arteries that's why I have to go into IVs so they use this in Japan to inject and then dissolve so they go into the artery they dissolve and they're resorbable so they cause a

like a light and Baalak effect and then they go away he found that these patients had a decrease in pain after doing knee embolization subsequently he published a paper on 72 patients 95 needs in which he had an

excellent clinical success clinical success was defined as a greater than 50% reduction in knee pain so they had more than 50% reduction in knee pain in 86 percent of the patients at two years 79 percent of these patients still had

knee pain relief that's very impressive results for a procedure which basically takes in about 45 minutes to an hour so we designed a u.s. clinical study we got an investigational device exemption actually Julie's our clinical research

coordinator for this study and these are the inclusion exclusion criteria we basically excluded patients who have rheumatoid arthritis previous surgery and you had to have moderate or severe pain so greater than 50 means basically

greater than five out of ten on a pain scale we use a pain scale of 0 to 100 because it allows you to delineate pain a little bit better and you had to be refractory to something so you had to fail medications injections

radiofrequency ablation you had to fail some other treatment we followed these patients for six months and we got x-rays and MRIs before and then we got MRIs at one month to assess for if there was any non-target embolization likes a

bone infarct after this procedure these are the clinical scales we use to assess they're not really so important as much as it is we're trying to track pain and we're trying to check disability so one is the VA s or visual analog score and

on right is the Womack scale so patients fill this out and you can assess how disabled they are from their knee pain it assesses their function their stiffness and their pain it's a little

bit limiting because of course most patients have bilateral knee pain so we try and assess someone's function and you've improved one knee sometimes them walking up a flight of stairs may not improve significantly but their pain may

improve significantly in that knee when we did our patients these were the baseline demographics and our patients the average age was 65 and you see here the average BMI in our patients is 35 so this is on board or class 1 class 2

obesity if you look at the Japanese study the BMI in that patient that doctor okano had published the average BMI and their patient population was 25 so it gives you a big difference in the patient population we're treating and

that may impact their results how do we actually do the procedure so we palpate the knee and we feel for where the pain is so that's why we have these blue circles on there so we basically palpate the knee and figure

out is the pain medial lateral superior inferior and then we target those two Nicollet arteries and as depicted on this image there are basically 6 to Nicollet arteries that we look for 3 on the medial side 3 on the lateral side

once we know where they have pain we only go there so we're not going to treat the whole knee so people come in and say my whole knee hurts they're not really going to be a good candidate for this procedure you want focal synovitis

or inflammation which is what we're looking for and most people have medial and Lee pain but there are a small subset of patients of lateral pain so this is an example patient from our study says patient had an MRI beforehand

of you have worked with cryoablation you know they have 12 different types of probes and each probe is a different Ice Bowl that they they mark it as all this

ice force probe creates a very oblong freeze and this ice rod will create a slightly different freezin you can use an ice pearl which is a more rounded freeze and that is that in order to get the length of the ice ball depends

really on the probe insulation so they've insulated the probe prior to even putting it into the packaging and in doing so you can predict the length of the ablation the diameter on the other hand depends on the rate of

transfer of energy right so if you're putting a lot of energy into that you can create a more rounded ice ball to a certain extent what I will point out in any ablation whether it's microwave or cryoablation propagation from the tip of

the needle from their tip of the antenna is what's most controlled right so if you don't want to damage something in general you want to point the needle directly at it it seems like it's counterintuitive but if for instance you

wanted to ablate near the aorta you want to point the needle right at the aorta because it doesn't come very far off the tip of the probe almost everything propagates backwards and to the side and you can't control that as much and so

kryos the same way that one's here so in

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